DE1086751B - Magnetic amplifier working as a relay - Google Patents

Description

The invention relates to a relay operating magnetic amplifier with at least one saturable core, which in turn carries at least one power winding fed with alternating current and a control winding fed with direct current, and a rectifier in series with the power winding and a transistor between the emitter and Base is connected to the output terminals of the magnetic amplifier, with one of the poles of the alternating current source for supplying the magnetic amplifier to earth, according to patent application C 15744 VIII a / 21 a ² . In the magnetic amplifier protected by the main patent application and working as a relay, the transistor connected to the output of the magnetic amplifier enables the output of a direct current which can assume two very specific values depending on the control ampere turns. In the switching arrangement according to the main patent application, the output of the magnetic amplifier is connected to a point common to both the emitter of a transistor and a resistor. At a certain value of the output current, the transistor becomes current-permeable, but with this arrangement there is no gain in current through the transistor, because the emitter current is somewhat larger than the collector current.

The object of the invention is to provide a magnetic amplifier operating as a relay which does not have this disadvantage.

The solution to this problem is according to the invention that the useful circuit of the transistor contains a load impedance which is applied on the one hand to the collector of the transistor and on the other hand to a second source for a constant voltage, and that an output terminal of the magnetic amplifier via the rectifier to a Point is placed, which is connected on the one hand to the base of the transistor and on the other hand is connected to ground via a resistor, while the emitter of the transistor is connected to a constant voltage source, such that the change in the strength of the output current of the magnetic amplifier a change in the potential of the base of the transistor has the consequence, whereby the transistor is either current-impermeable or current-permeable. Under these conditions, the transistor becomes current-permeable when the potential of the output terminal of the magnetic amplifier becomes negative enough; the current in the base, on the other hand, is much smaller than the collector current, and in this way receives a current gain. In addition, it is also possible to control the current in the base of the transistor through a resistor, which is placed between the output terminal of the magnetic amplifier and the base
amplifier

Addition to patent application C 15744 VIII a / 21a ²
(Auslegeschrift 1 074 086)

Applicant:

Compagnie Industrielle

des Telephones Soc. At.,

Paris

Representative: Dipl.-Ing. H. Leinweber, patent attorney,
Munich 2, Rosental 7

Claimed priority:
France June 2, 1958

Claude Monin, Villennes-sur-Seine, Seine-et-Oise

(France),
has been named as the inventor

of the transistor is switched to reduce even further.

Further features and advantages of the invention emerge from the following description. In the The drawing is an embodiment of a magnetic amplifier operating as a relay, for example shown.

Fig. 1 is the circuit arrangement of a relay operating magnetic amplifier according to the invention;

Fig. 2 is a modified embodiment of the circuit arrangement of Fig. 1, and the

FIGS. 3 to 8 show curves relating to the operation of the arrangement according to FIG. 1.

The illustrated in Fig. 1, working as a relay magnetic amplifier has a saturable core S ₁ , on which several windings a, b, c and d are wound. The winding α lying in series with a rectifier Rd is fed from an alternating current source AB , and the rectifier Rd is designed so that it only allows the negative half-waves to pass. Direct currents flow through windings b, c and d; the winding & is a control winding,

009 570/283

winding c is a polarization winding and winding d is a reaction winding; In any case, the term “control ampere turns” is to be understood here as basically the algebraic sum of the ampere turns of the windings b, c and d. The winding α is connected to the rectifier Rd at a point D which is connected on the one hand to the base ba of a transistor T and on the other hand to earth via a resistor R _2. The emitter e of the transistor T is connected directly to the negative pole of a DC voltage source U ₀ . If the connection NQ is established, then the collector Co of the transistor is connected to the negative pole of a DC voltage source U _R via a load resistor R _c , the absolute value of U% being considerably greater than U ₀ (for example, Ur = 48 volts and U. ₀ = 1.5 volts). One layer of a capacitor Ca is placed at point F of the collector, the other layer of which is connected to earth. The reaction winding d can be placed in the output circuit of the magnetic amplifier by breaking the connection NQ and making connections MN and PQ.

The circuit arrangement according to FIG. 2 differs from that according to FIG. 1 only in two points: On the one hand, a resistor R _{1 has been connected} between the output terminals of the magnetic amplifier and the base of the transistor in order to reduce the current in the base; because the corresponding current at the emitter is much stronger, the resistance value R ₁ is chosen so that the desired current strength is obtained in the load resistor, which is known to be somewhat smaller than that in the emitter; on the other hand, a resistor R _{p has been} switched on between point F and the collector, the meaning of which will be explained later.

3 shows the curve G _{1 of} the output current I _{m of} the magnetic amplifier, which flows through the winding α and the rectifier Rd , as a function of the control ampere turns which the windings b and c supply.

Since the transistor shown in Fig. 1 has been assumed to be of the pnp type, its emitter e must be positive with respect to the base in order to be conductive. Since the emitter is connected to a negative polarity and the rectifier Rd only lets through the negative half-waves, the following inequality must exist:

- U ₀ > -R ₂ I ₀ or J ₀ >

U ₁

where I _{0 is} the smallest output current of the magnetic amplifier, above which the transistor is current-permeable; as a result, it has the meaning of a threshold value current.

FIG. 4 shows curve G _{1 of FIG. 3 on the one hand and curve G 2 of} the threshold value current I ₀ on the other hand, which is obviously constant for a given circuit arrangement. Curve G ₂ intersects curve G ₁ at two points S ₁ and S ₂ , which correspond to the control ampere turns (N _c I _c ) t and (N _c I _c ) s, respectively; the current intensities I _m , which make the transistor current-permeable, are therefore above the curve G ₂ for I _c . These values are _{illustrated by curve G 3} in FIG. 5.

The current in the collector follows exactly the changes in the current in the emitter to the extent that how the collector voltage becomes smaller compared to the base voltage. Stabilized beyond this limit the current is exactly to a value which corresponds to the equality of the voltages of the base and the Collector corresponds.

So this amperage is the same

_T Ur - potential of the base

The curve G ₁ of FIG. 6 represents the current / _s = I ₁ in the load resistor R _c . It can be seen from this figure that the output current for values of the ampere-turns N _c I _c which are greater than (N _C I _C ) _T , suddenly rises from the value zero to the constant value I _1. The potential of the point F (see FIG. 2), which represents the potential of a coating on the capacitor Ca , therefore suddenly rises from the value - U% to a value which is close to zero; the greater part of the capacitor Cd discharges through the transistor T ; the resistor R _p is a protective resistor that limits the discharge current of the capacitor. An analogous fact would exist at the moment in which the output current / _s becomes zero.

The resistors R ₁ and R ₁ are therefore by no means indispensable for the operation of the magnetic amplifier according to the invention according to the above considerations; their involvement is moreover independent of one another; FIG. 2, in which the two resistors are drawn, represents a modified embodiment of the subject matter of the invention, which makes it possible to do justice to certain special circumstances.

If the useful current is sent to the reaction winding by breaking the connection NQ and making the connections MN and PQ , then the output current for N _c I _c = 0, as shown in FIG. 7, is through the intersection of the straight line D with the curve G ₄ , i.e. given by the point A ₀ . The slope of the straight line D is given by the ratio of the number of turns of the reaction winding D to the number of turns of the control windings b and c . The characteristic operating point in the event that N _C I _C should differ from zero is given by the intersection of curve G ₄ with a straight line which is derived from straight line D by a parallel shift to the abscissa axis and the algebraic value N _c I _c owns.

Thus, it is clearly seen that for N _c I _c = (N _c I _{C) T,} the straight line D _1, curve G ₄ in B ₁ and A ₁ intersects that for N _C I _C = (N _C I _{C) R is} the Straight line D ₂ intersects curve G ₄ in B ₂ and A _b and that for AT ₀ I _C <C (N _C I _C ) _{R there is} always only one possible point of intersection.

The curve G ₅ in FIG. 8 is the actual characteristic curve for the magnetic amplifier according to the invention, which finally results in an output current of zero for N _c I _c <C (N _c I _c ) n , for (N _C I _C ) _R < .N _C I _C <(Ar _e / _c ) _T results in either a zero current or a current of constant strength I , depending on whether N _c I _c has assumed its value with increasing or decreasing amounts.

The point B _v, which corresponds to the value (N _C I _C ) _T , and the point B ₂ , which corresponds to the value (N _C I _C ) _R , are called the rise point or working point or return point or rest point.

Claims (7)

Patent claims: 1. Magnetic amplifier working as a relay with at least one saturable Core, which in turn has at least one power winding fed with alternating current and one with Direct current fed control winding carries, and a rectifier lying in series with the power winding as well as a transistor which is connected between emitter and base to the output terminals of the magnetic amplifier, whereby one of the poles of the alternating current source for feeding the magnetic amplifier is connected to earth, according to patent application C 15744 VIII a / 21 a ² , characterized in that the useful circuit of the transistor (T) contains a load impedance (R _c ) which on the one hand to the collector (Co) of the transistor (T) and on the other hand to a second source (U _R ) for a constant voltage is applied, and that an output terminal of the magnetic amplifier is connected via the rectifier (Rd) to a point (D) which is connected on the one hand to the base (ba) of the transistor (T) and on the other hand via a resistor (A ₂ ) Ground is laid, while the emitter (e) of the transistor (T) is connected to a constant voltage source (U ₀ ) , such that the change in the strength of the output angsstromes of the magnetic amplifier has a change in the potential of the base (ba) of the transistor (T) result, whereby the transistor is either current-impermeable or current-permeable. 2. Magnetic amplifier according to claim 1, characterized in that the power winding (a) of the magnetic amplifier on the one hand to the alternating current source (A) and on the other hand via a rectifier (Rd) to the base (ba) of the transistor (T), which only has the negative half-waves passes, the emitter (e) of the transistor is connected to the negative pole of the source (CZ ₀ ) for constant voltage and the load impedance (R _c ) is connected to the negative pole of the second source (Ur) for constant voltage. 3. Magnetic amplifier according to claims 1 and 2, characterized in that a resistor (R ₁ ) is switched on between the rectifier (Rd) and the base of the transistor (T) (Fig. 2). 4. Magnetic amplifier according to Claims 1 and 3, characterized in that the collector (Co) of the transistor (T) is connected to earth via a filter capacitor (Ca). 5. Magnetic amplifier according to claims 1 and 4, characterized in that a protective resistor (R _p ) is switched on between the collector (Co) of the transistor (T) and the point (F) connected to the filter capacitor (Ca) (Fig.2 ). 6. Magnetic amplifier according to claims 1 and 5, characterized in that the useful circuit consists of a load resistor (R _c ) which is in series with the protective resistor (R _p ) , which in turn is connected to the collector (Co) of the transistor (T) is connected, and that one layer of the filter capacitor (Ca) is connected to a point (F) of the circle which lies between the two resistors (R _p , R _c ) and the other layer connected to earth, such that the charging - or the discharge current of the capacitor (Ca), limited by the protective resistor (R _p ), does not endanger the transistor (T). 7. Magnetic amplifier according to one of claims 1 to 6, characterized in that the useful circuit contains a reaction winding (d) which is located on the magnetic core (^ ₁ ) of the magnetic amplifier and between the collector (Co) of the transistor (T) and the load resistor (R _c ) is switched on. 1 sheet of drawings ©. 009 570/283 8.60